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1
Synthesis, Pharmacological Characterization and QSAR
Modelling of 4-Phenylpiperidines and 4-Phenylpiperazines
Effects on the dopaminergic neurotransmission in vivo
Fredrik Pettersson
Department of Chemistry and Molecular Biology
University of Gothenburg
2012
DOCTORAL THESIS
Submitted for partial fulfilment of the requirements for the degree of
Doctor of Philosophy in Chemistry
UNIVERSITY OF GOTHENBURG
2
Synthesis, Pharmacological Characterization and QSAR Modelling of 4-Phenyl-piperidines and
4-Phenylpiperazines - Effects on the dopaminergic neurotransmission in vivo
Fredrik Pettersson
© Fredrik Pettersson
ISBN: 978-91-628-8588-5
http://hdl.handle.net/2077/31366
Department of Chemistry and Molecular Biology
University of Gothenburg
SE-412 96 Göteborg
Sweden
Printed by Kompendiet, Aidla Trading AB
Göteborg, 2012
3
In loving memory of my mother Inga-Maj
4
5
Abstract
The endogenous neurotransmitter dopamine (DA) is involved in several functions that are
controlled from the central nervous system (CNS), for example behaviour, memory, cognition and
reward. A disturbed dopaminergic neurotransmission may lead to many severe conditions, such as
schizophrenia, attention deficit hyperactivity disorder (ADHD) or Parkinson's disease (PD). The
dopamine receptors belong to the G-protein coupled receptors (GPCRs) and are divided into five
distinct subtypes (D1-D5). These subtypes can be either of the D1- or D2-types based on their effect
on the production of cyclic adenosine monophosphate (cAMP). The most common dopaminergic
receptor used as target for pharmaceuticals is by far the D2 receptor and drugs acting as full
agonists, partial agonists and antagonists at this receptor have been developed.
In the search for new dopaminergic ligands, a set of 4-phenylpiperidines and 4-
phenylpiperazines have been synthesized and their effects have been tested in both in vivo and in
vitro assays. Starting with the known partial agonist 3-(1-benzylpiperidin-4-yl)phenol, stepwise
structural modifications of functional groups afforded mainly D2 antagonists but with a conserved
preference for binding to the agonist binding site and fast dissociation rates from the receptor.
However, further modifications, including changes of the position of the aromatic substituent,
indicated that other targets than the D2 receptor was involved and binding affinity studies later
concluded that some of these compounds had MAO A inhibiting properties. In order to fully
elucidate what structural properties are related to the different pharmacological responses, QSAR
models with physicochemical descriptors set against each respective response were acquired by
means of partial least square (PLS) regression. Models with high predictivity (Q2>0.53) were obtained
and the interpretation of these models has provided an improved understanding of how structural
modifications in this chemical class affect the response both in vivo and in vitro. The structural
motifs that were investigated included the position and physicochemical properties of the aromatic
substituent as well as the heterocycle being a piperazine or a piperidine. All these properties turned
out to be significant for the different responses in some aspect. In addition, a strong correlation
between the affinities to the D2 receptor and to MAO A and the levels of the metabolite DOPAC in
striatum has been established. This led us to the conclusion that it is primarily interactions with
these two targets that lead to the in vivo response observed for this class of compounds.
_______________________________________________________________________________
Keywords: dopamine, D2, monoamine oxidase, DOPAC, in vivo, QSAR, dopaminergic stabilizer
6
Papers included in the thesis This thesis is based on the following publications and manuscripts:
I. Synthesis and evaluation of a set of 4-phenylpiperidines and 4-phenylpiperazines as D2
receptor ligands and the discovery of the dopaminergic stabilizer 4-[3-
(methylsulfonyl)phenyl]-1-propylpiperidine (Huntexil, Pridopidine, ACR16).
Pettersson F, Pontén H, Waters N, Waters S, Sonesson C.
J Med Chem. 2010 Mar 25; 53(6):2510-20.
II. Synthesis and Evaluation of a Set of para-Substituted 4-Phenylpiperidines and 4-
Phenylpiperazines as MAO Inhibitors.
Pettersson F, Svensson P, Waters N, Waters S, Sonesson C.
J Med Chem. 2012 Apr 12;55(7):3242-9
III. Synthesis, Pharmacological Evaluation and QSAR Modeling of mono-Substituted 4-
Phenylpiperidines and 4-Phenylpiperazines
Pettersson F, Svensson P, Waters N, Waters S, Sonesson C.
Eur J Med Chem. 2012, Submitted
IV. New quantum mechanically derived electronic principal properties of aromatic
substituents.
Sunesson Y, Norrby P. O., Pettersson F, Sonesson C and Svensson P.
Manuscript
Reprints were made with permission from the journals.
7
Contributions to the Papers
I. Planned and synthesized most of the included compounds; Extracted the rawdata and
calculated the correlations; interpreted results and wrote the manuscript
II. Planned and synthesized most of the included compounds; Tabulated data from the
rawdata and calculated the correlations and QSARs; interpreted results and wrote the
manuscript
III. Planned and synthesized most of the included compounds; Tabulated data from the
rawdata and calculated the correlations and QSAR; interpreted results and wrote the
manuscript
IV. Provided the data set necessary for comparison; wrote parts of the manuscript, assisted
with calculations of QSAR models; provided feed-back and managed the format
8
Contents
1. Introduction
1.1. Monoaminergic Neurotransmitters.........................................................................................1
1.1.1. Catecholamine Synthesis and Catabolism................................................................. 1
1.1.2. Monoamine Oxidases................................................................................................. 4
1.1.3. Dopamine Receptor Subtypes.................................................................................... 4
1.1.4. The Dopamine D2 Receptor....................................................................................... 5
1.2. Clinical Aspects of Dopaminergic Drugs.............................................................................. 6
1.2.1. Schizophrenia............................................................................................................. 6
1.2.2. Neurological Diseases................................................................................................ 7
1.3. Dopamine D2 Ligands............................................................................................................ 7
1.3.1. DA D2 Agonists........................................................................................................... 7
1.3.2. DA D2 Antagonists...................................................................................................... 8
1.3.3. DA D2 Partial Agonists............................................................................................... 9
1.3.4. Dopaminergic Stabilizers........................................................................................... 9
1.4. Structure Activity Relationships........................................................................................... 11
1.4.1. Phenylpiperidines and Phenylpiperazine.................................................................. 11
1.4.2. D2 Ligands................................................................................................................. 12
1.4.3. MAO Inhibitors......................................................................................................... 14
1.4.4. Quantitative structure activity relationships (QSARs).............................................. 15
1.4.5. Drug Design.............................................................................................................. 16
2. Aims............................................................................................................................................ 19
3. Chemistry
3.1. Original Synthetic Route to Pridopidine (Paper I)................................................................ 21
3.2. Suzuki Cross Coupling between Phenylbromides and 1-Pyridyl-4-boronic acid (Paper III)23
3.3. Buchwald-Hartwig Cross Coupling between Phenylbromides and Piperazines (Paper III). 24
3.4. Convertion of Functional Groups.......................................................................................... 26
3.4.1. Aniline to Morpholine (Paper II).............................................................................. 26
3.4.2. Phenols to Mesylates and Triflates (Paper III)......................................................... 26
3.4.3. Triflate to Nitrile (Paper III) .................................................................................... 27
3.4.4. Phenols to Alkoxy-groups (Paper II and III) ............................................................ 28
4. Pharmacology
4.1. Methods................................................................................................................................. 29
4.1.1. In vitro models........................................................................................................... 29
4.1.2. In vivo models............................................................................................................ 30
4.2. Results................................................................................................................................... 32
9
4.2.1. In Vitro Binding: D2High
, D2Low
, MAO A and MAO B and Intrinsic Activity at D2
Receptors (Paper I-III).................................................................................................. 33
4.2.2. In Vivo Effects: Neurochemistry and Locomotor Activity........................................ 36
5. Quantitative Structure Activity Relationships
5.1. QSAR models of in vivo and in vitro responses (Paper III) ................................................. 39
5.2. Development of new electronic descriptors (Paper IV) ....................................................... 43
6. Ligand-Target interactions at MAO A and D2 receptors...................................................... 45
7. Concluding Remarks................................................................................................................ 51
8. Acknowledgement..................................................................................................................... 53
9. Appendices................................................................................................................................. 55
10. References.................................................................................................................................. 57
10
Abbreviations
3-MT
3-Methoxytyramine
5-HT
5-Hydroxytryptamine (serotonin)
COMT
Catechol-O-methyltransferase
DA
Dopamine
DOPAC
3,4-Dihydroxyphenylacetic acid
EDG
Electron donating group
EWG
Electron withdrawing group
GPCR
G-protein-coupled seven-transmembrane receptor
HA
Hydrogen bond acceptor
HD
Hydrogen bond donor
HVA
Homovanillic acid
HPLC
High performance liquid chromatography
IA
Intrinsic activity
Ki
Binding affinity constant
LMA
Locomotor activity
NE
Norepinephrine
OPLS
(Orthogonal) partial least square
PD
Parkinson’s disease.
QSAR
(Quantitative) structure-activity relationship
VolR,
Calculated volume.
π
Calculated hydrophobicity
σm
Hammett´s sigma meta
σp
Hammett´s sigma para
µR
Group dipole moment
11
1. INTRODUCTION
1.1 Monoaminergic Neurotransmitters
Neurotransmitters are a group of endogenous chemicals that transmit an impulse from a neuron to a
target cell across a synaptic cleft. Neurotransmitters can be broadly split into two groups – the small
molecule neurotransmitters and the relatively larger neuropeptide neurotransmitters. Within the
category of small molecule neurotransmitters are the monoaminergic neurotransmitters, consisting
of one amino group attached to an aromatic moiety by a two carbon chain. They are synthesized in
the body from different amino acids (a.a.) and belong to specific subclasses depending on which
a.a. they are derived from. The major monoamine subclasses active in the brain are the
catecholamines and the tryptamines. Dopamine (DA, 1, Figure 1) and norepinephrine (NE, 2,
Figure 1) belong to the catecholamines and serotonin (5-HT, 3, Figure 1) belongs to the tryptamine
class.
Figure 1. The monoamines: dopamine (1), norepinephrine (2) and serotonin/5-HT (3).
1.1.1 Catecholamine Synthesis and Catabolism. Since the catecholamines are unable to penetrate
the blood-brain barrier (BBB), they have to be synthesised in the brain by specific enzymes (Figure
2). The precursor for catecholamine synthesis is tyrosine, an amino acid that is able to penetrate the
BBB by a specific carrier. Tyrosine is oxidized to the catechol 3,4-dihydroxyphenylalanine (DOPA)
by tyrosine hydroxylase and DOPA is then converted to dopamine (DA) by the enzyme aromatic L-
amino acid decarboxylase. Hydroxylation of DA by dopamine β-hydroxylase produce
Norepinephrine (NE) and N-methylation by phenylethanolamine N-methyltransferas leads to
epinephrine (E). However, from here on the focus of this work will be limited to dopamine.
1 2 3
12
Figure 2. The synthesis of catecholamines
After being synthesized in the cytosol, dopamine is stored in presynaptic vesicles waiting for a
signal. Neurotransmission occurs when an action potential causes the newly synthesised dopamine
to be released into the synaptic cleft. There it activates post-synaptic receptors, which in turn
propagate the signal further along the postsynaptic neuron. In addition, dopamine also affects pre-
synaptic receptors, resulting in a feed-back control of the continued synthesis and release of
neurotransmitters into the synaptic cleft (Figure 3).
Tyrosine
DOPA
Dopamine
Norepinephrine
Epinephrine
Aromatic L-amino acid decarboxylase
Dopamine β-hydroxylase
Phenylethanolamine N-methyltransferase
Tyrosine hydroxylase
13
Figure 3. The dopamine neurone
After exerting its effects at the synapse, dopamine is cleared from the synaptic cleft by either
reuptake or degradation; leading to a termination of the signalling. The degradation of dopamine in
the brain is primarily mediated through two enzymes: monoamine oxidase (MAO) and catechol-O-
methyl transferase (COMT). MAO metabolizes DA into 3,4-dihydroxyphenylacetaldehyde
(DOPAL) which is further metabolized into 3,4-dihydroxyphenylacetic acid (DOPAC) by the
enzyme aldehyde dehydrogenase (ALDH). COMT then methylates DOPAC to homovanillic acid
(HVA), which is excreted via the urine. COMT is also able to directly metabolize dopamine,
producing 3-methoxytyramine (3-MT) which in turn can be metabolized by MAO/ALDH into HVA
(Figure 4).
14
Figure 4. Metabolism of dopamine (DA) into 3,4-dihydroxyphenylacetic acid (DOPAC), 3-
methoxytyramine (3-MT) and homovanillic acid (HVA) by monoamine oxidase (MAO), aldehyde
dehydrogenase (ALDH) and catechol-O-methyl transferase (COMT).
1.1.2. Monoamine Oxidases. There are two distinct types of MAOs, MAO A and MAO B, which
share 70% amino acid sequence homology.1-5
They are tightly bound to the outer membrane of the
mitochondrion in the liver and in the brain.6 Both MAO A and MAO B catalyze the oxidative
deamination of 5-HT, DA and NA in the brain, albeit in rats this reaction is preferentially catalyzed
by MAO A.7, 8
Furthermore, MAO A is the isoform found primarily within dopaminergic nerve
terminals9 whereas MAO B is found mainly in striatal neurons and glial cells.
10 Thus, in rats it is
mainly MAO A that affect the DA catabolism leading to production of the metabolite DOPAC and
therefore MAO A inhibitors (e.g. clorgyline) reduces striatal DOPAC levels in vivo.6, 11
In addition,
when the MAO-mediated metabolism is blocked, more synaptic DA is metabolized by COMT to 3-
MT and less 3-MT is metabolized to HVA by MAO (Figure 3 and 4), leading to a concomitant
increase in 3-MT levels.
1.1.3. Dopamine Receptor Subtypes. In 1979, Kebabian et al. characterized two subtypes of the
DA receptor as D1 and D2.12
The location and function of these two receptors has since then been
extensively investigated.13-17
Even though there is some overlap in their distribution in the CNS,
their pharmacological profiles are quite diverse. Both subtypes belong to the G-protein coupled
3-MT
MAO
ALDHCOMT
COMT
DA
DOPAC
HVA
MAO
ALDH
15
seven-transmembrane receptors (GPCRs), but where the D1 receptor interacts with the Gs type
protein, resulting in an activation of the adenylate cyclase enzyme and subsequent increased
production of cyclic adenosine monophosphate (cAMP), the D2 receptor instead interacts with the
Gi complex, rendering an inhibition of the cAMP production. More recently, three additional
subtypes of the DA receptor have been characterized, namely D3, D4 and D5. Based on their amino
acid sequences and structural similarities, D5 has been identified as a D1-like receptor,18
while D3
and D4 have been classified as D2-like.13, 16, 17, 19, 20
Sequencing has shown 75% similarity between
the transmembrane regions of D2 and D3 while a corresponding number for D2/D4 is 53%.21
However, even though the homology is high, studies on their respective distribution and function
have revealed some substantial diversity between the different subtypes.21
This is also reflected in
the respective in vivo responses of subtype specific compounds. For example, D3 agonists induce
hypoactivity in rats at doses where the synthesis and release of DA is unaffected, providing
evidence that D3 function mainly a postsynaptic receptor.22-25
The role of the D3 and D4 receptors in
neuropsychiatric and neurological conditions have been studied extensively, and while D3 is
claimed to be involved in several different brain disorders (e.g. schizophrenia, substance abuse etc.),
the D4 receptor holds less promise as a drug target in this area.21, 26, 27
1.1.4. The Dopamine D2 Receptor
Dopamine type 2 receptors (D2) are mainly located in the structure of the mammalian brain known
as the basal ganglia, but are also present in other areas, for example the cortex. Dopamine in the
brain exerts its action by means of synaptic as well as extrasynaptic release, affecting postsynaptic,
presynaptic and dendritic D2 receptor populations. DA acts as a high-affinity neurotransmitter at the
D2 receptor allowing for low concentration tonic signalling of the dopaminergic system. In addition,
the system can respond to short surges of DA evoked by event-related firing of the dopaminergic
neurons.21
Two isoforms of the D2 receptor are generated by differential splicing of the same gene
and have been termed D2S (D2-short) and D2L (D2-long).28, 29
These two alternatively spliced
isoforms differ in the third intracellular loop (i.e. by the presence of 29 additional amino acids in
D2L), causing some diversity in their anatomical, physiological, signaling, and pharmacological
properties. D2S has been shown to be more densely expressed presynaptically and to be more
involved in the autoreceptor functions, whereas D2L seems to be the main isoform
16
postsynaptically.30, 31
Presynaptic autoreceptors provide a negative feedback system that controls
firing, synthesis and release of DA in response to extracellular neurotransmitter levels.32-34
Besides
the different splice isoforms, the D2 receptor population can be distributed between two "activity-
states"; either a resting, low-affinity state (D2Low
) or a catalytically active, high-affinity state (D2High
)
in which DA binds with higher affinity.20, 35
1.2. Clinical Aspects of Dopaminergic Drugs
DA was first recognized in 1958 by Arvid Carlsson and Nils-Åke Hillarp at the Laboratory for
Chemical Pharmacology of the National Heart Institute of Sweden.36
Carlsson et al. demonstrated
that reserpine depleted the levels of DA in the brain and that subsequent injection of L-DOPA
restored these levels.37
Furthermore, reserpine was discovered to induce catalepsy in both rabbit and
cat, and administration of L-DOPA gave an acute reversal of the said symptoms. These findings
subsequently led to the theory of DA's role in the control of motor functions and possible
involvement in the pathophysiology of Parkinson's disease (PD)38
, a theory that was soon proven
correct (Ehringer et al.39
).
Since the initial discovery of DA's presence in the brain, a great deal of effort has been made to
investigate how DA affects the CNS, in the normal state as well as in disrupted systems. For
example, the role of DA in the reward system has been extensively studied in order to understand
addiction and finding suitable drugs to treat such disorders.40-43
1.2.1. Schizophrenia. One of the fields where dopaminergic drugs have had the most profound
impact is schizophrenia, where the DA hypothesis for a long time has been the leading
pathophysiologic theory, and DA blocking drugs has been the standard treatment since the 1950's.
Schizophrenia is a severe, world-wide disease affecting about 1% of the population. The symptoms
are divided into positive (hallucinations, delusions etc.), negative (lack of motivation, anhedonia,
etc.) and cognitive (memory- and attention-deficits).44
The search for an ideal treatment of
schizophrenia has moved from D2-antagonists (e.g. haloperidol (6) and chlorpromazine) introduced
in the 1950's,45, 46
to atypical antipsychotics of various types and with a broad spectrum of
mechanisms (e.g. clozapine, aripirazole etc.).47
Although traditional D2-antagonist antipsychotics
are efficacious for the positive symptoms, they are also responsible for extrapyramidal side effects
17
(EPS) which occur as a result of excessive attenuation of brain DA neuronal activity due to the
blockade of postsynaptic DA receptors.48, 49
1.2.2. Neurological Diseases. As mentioned earlier, PD was the first disease where the involvement
of DA in the brain was proven, and L-DOPA is still the main treatment for this condition. Since
then, the importance of DA for both motor and cognitive functions in the patophysiology of many
neurological diseases and disorders has been understood. Besides PD, dopaminergic drugs have also
been found useful in the treatment of Huntington´s disease (HD), restless leg syndrome (RLS),
Tourette's syndrome and attention deficit hyperactivity disorder (ADHD). The pharmacological
profiles of the drugs used to treat these disorders are quite diverse, from DA antagonists in RLS and
Tourette's syndrome to DA reuptake inhibitors in ADHD. In HD, the vesicular monoamine
transporter (VMAT)-inhibitor tetrabenazine has shown to be effective in treatment of chorea.50
However, there are many aspects of this disease and an effective treatment option for other
symptoms is still being sought for. Recent clinical trials have shown promising results for the
dopaminergic stabilizer pridopidine (ACR16, Huntexil®) (16, Figure 7) with beneficial effects on
several manifestations of HD and a very favorable side effect profile.
1.3. Dopamine D2 Ligands
Drugs that interact with the agonist binding site of D2 receptors can be described as full agonists,
partial agonists or antagonists/inverse agonists51
and a number of such drugs have well-established
applications in the treatment of various neurological and psychiatric disorders. The association and
dissociation rate constants, kon and koff, besides defining the equilibrium state also describe how fast
the ligand associate to and dissociate from the receptor system. Moreover, it has been proposed that
the occurrence of side effects (e.g. extrapyramidal symptoms and sustained hyperprolactinaemia) of
antipsychotic drugs is directly linked to the long D2 dissociation rates.52-54
1.3.1. DA D2 Agonists. In vitro, the D2 agonists preferentially displaces agonist ligands over
antagonist ligands in binding assays and induce a full catalytic reaction in functional assays (i.e.
they have high intrinsic activity).55-57
In vivo, the full D2 agonists induce a decrease in DA release
18
through activation of presynaptic autoreceptors and affect locomotor activity in a biphasic manner
(i.e. first decreased, then increased activity). The biphasic effect on behaviour is dose dependent and
caused by differences in sensitivity between the autoreceptors and the postsynaptic receptors. In
general, the autoreceptors are more sensitive and low doses of agonist only activate this population,
leading to a decrease in DA release and a concomitant diminished locomotor activity. At higher
doses, postsynaptic receptors are also affected with behavioural stimulation as a result. Examples of
full D2 agonists are DA (1), quinpirole (4) and ropinirole (5).
1.3.2. DA D2 Antagonists. In contrast to the agonists, the D2 antagonists in general show no
preference in displacing agonist over antagonist ligands in binding assays and they induce no
catalytic reaction in functional assays. In vivo, D2 antagonists induce an increase in DA release
through blockage of presynaptic autoreceptors and decreased locomotor activity through inhibition
of postsynaptic receptors. D2 antagonists are by far the most common type of dopaminergic ligands
in medicine, for example haloperidol (6) and risperidone (7) used to treat schizophrenia (Figure 5).
Figure 5. Dopamine antagonists haloperidol (6), risperidone (7) clozapine (8) and quetiapine (9).
4 5
89
67
19
1.3.3. DA D2 Partial Agonists. D2 partial agonists, much like full agonists, in general
preferentially displace agonist ligands over antagonist ligands in binding assays.58
However, the
partial agonists do not induce a full catalytic response in functional assays (i.e. they have lower
intrinsic activity than the full agonist). In vivo, partial D2 agonists affect DA release and locomotor
activity differently depending on the level of intrinsic activity. If the level of intrinsic activity is
very low, the in vivo effects are similar to those of an antagonist while higher intrinsic activity
induces more agonist-like effects. The D2 partial agonist aripiprazole (10, Figure 6) has very low
intrinsic activity59, 60
and is therefore thought to act as either a functional agonist or a functional
antagonist, depending on the initial levels of DA. Aripiprazole has been approved for the treatment
of schizophrenia, bipolar disorder and depression.
Figure 6. Dopamine partial agonists aripiprazole (10), (–)-3PPP (11), bifeprunox (12), piribedil (13) and
pardoprunox (14).
1.3.4. Dopaminergic Stabilizers. For the last decades the bulk of medicinal chemistry
optimization programs have generated high-affinity drugs with slow drug–receptor kinetics. In the
meantime, limited attention has been set on optimizing D2 ligands with low in vitro affinity and
receptor kinetics comparable to those of natural DA signaling. Studies have shown that DA D2
receptor kinetics differs among antipsychotic compounds and it has been proposed that fast-off
kinetics (high koff) is a requirement for atypicality.54, 61
This is a new approach towards determining
what properties are important in order to achieve an optimal antipsychotic profile with low
propensity for side effects and the dopaminergic stabilizers have been characterized in vitro as low
13 14
10
11
12
20
affinity D2 receptor ligands with fast-off receptor kinetics.62, 63
It is however the in vivo effect that
singles out the dopaminergic stabilizers from other D2 ligands, having the ability to counteract
states of both hyperactivity and hypoactivity, depending on the prevailing dopaminergic tone. To
date, four dopaminergic stabilizers have been developed, namely (3S)-3-(3-methylsulfonylphenyl)-
1-propylpiperidine ((-)-OSU-6162; 15, Figure 7), 4-(3-methylsulfonylphenyl)-1-propylpiperidine
(pridopidine; 16, Figure 7), 1-ethyl-4-(2-fluoro-3-methylsulfonyl-phenyl)piperidine (ordopidine; 17,
Figure 7) and 1-ethyl-4-(3-fluoro-5-methylsulfonyl-phenyl)piperidine (seridopidine; 18, Figure 7).
Pridopidine has shown unique effects in clinical studies for symptomatic treatment of Huntington´s
disease (HD) while 15 is being tested for treatment of alcohol dependence.64
Other areas where
dopaminergic stabilizers have shown promising results are PD, L-DOPA induced dyskinesia (LID),
schizophrenia and stroke/traumatic brain injury.65, 66
Figure 7. Dopaminergic stabilizers S-(-)-OSU6162 (15), pridopidine (16), ordopidine (17)
and seridopidine (18).
17 18
15 16
21
1.4. Structure Activity Relationships
Structure activity relationships (SARs) describe the relationship between the structure of a molecule
and its biological/pharmacological activity. There are different ways to describe a molecule and
thus different ways to produce a SAR, for example using the 3D-structure or physicochemical
properties of parts of, or the entire, molecule. The biological/pharmacological activity also includes
a wide range of different parameters, like in vitro affinity to a certain receptor or the locomotor
activity of a living animal. The SAR enables the medicinal chemist to understand how chemical
modifications affect the biological response and this knowledge can be used to produce new
compounds with a desired profile.
1.4.1 Phenylpiperidines and Phenylpiperazines. As structural backbones for pharmacologically
active compounds, phenylpiperidines and phenylpiperazines have been extensively studied for
several different targets. For example, many 5-HT ligands are based on these structures, like the 5-
HT1A agonist fluprazine (19), the SSRI paroxetine (20) and the 5-HT2A antagonist nefazodone (21).
Other targets where phenylpiperidines and phenylpiperazines have been investigated as potential
ligand scaffolds include GABA, NMDA and the adrenergic receptors. However, the main use of
these structures in medicinal chemistry has been as dopaminergic ligands. Haloperidol (6), as
21
19 20
22
mentioned previously, is a D2 antagonist and one of the first classical neuroleptics used as a
treatment option in schizophrenia. Since then, many 4-phenylpiperidine analogues have been
studied for their dopaminergic effects and potential use as antipsychotics. The partial D2 agonists
aripiprazole (10) and bifeprunox (12) instead have the phenylpiperazine backbone and a lot of
attention has been devoted to find D2/D3 ligands in this structural class. Most series of
phenylpiperidines and –piperazines acting on the D2/D3 receptors have an additional aromatic
moiety attached at the basic amine and a linker of varying length in between. The linker has proved
important for the D2/D3 selectivity and recent publications have concluded that the binding cavity in
the extracellular loop region of D2 is significantly shallower than the D3 counterpart.67, 68
The same
group also reported compounds selective for both D2 (SV-III-130s (22) and SV293 (23))67
and D3
(24)69
receptors, but for most D2-type ligands the affinities to these subtypes are similar. The D4-
ligand L-745870 (25)70
is also of the phenylpiperazine class and the bulky N-substituent is proposed
to be favorable for selectivity over D2.
1.4.2. D2 Ligands. Most compounds affecting the D2 receptor has at least one aromatic moiety and
one basic amine. In general, the agonists are relatively small, hydrophilic molecules whereas the
antagonists are usually larger and more lipophilic.71
Furthermore, the full agonists have certain
pharmacophore elements that usually are required in order to achieve a full catalytic response at the
D2 receptor, for example a hydrogen bonding aromatic substituent (preferable in the meta position)
and the basic amine in a position that resembles that of DA itself (e.g. 5-OH-DPAT (26) and
23
2524
22
23
quinpirole (4)).58
The D2 receptor antagonists bind to the receptor but do not activate the G-protein
and these compounds are usually of a bulky and hydrophobic character. D2 receptor antagonists
usually consist of two aromatic moieties with a basic amine in between (e.g. haloperidol (6) and
risperidone (7)) and molecular modelling based on closely related receptor structures (i.e. D3 and
β2) have confirmed that hydrophobic interactions of the aromatic parts stabilize the inactive
conformation.72, 73
The SAR of partial D2 agonists is more complex and both small and hydrophilic and bulky and
hydrophobic structures with this profile have been developed. 3-[(3S)-1-Propyl-3-piperidyl]phenol
((–)-3PPP; 11) is a partial agonist while the corresponding R-enantiomer (27) is a full agonist74
and
alignment of these two molecules with rigid full agonist analogues has revealed that the R-
enantiomer fits perfectly while the aromatic ring and basic nitrogen of the S-enantiomer are unable
to adapt the "right" conformation.58, 74
3-(4-Benzylpiperazin-1-yl)phenol (29) first published by
Mewshaw et al.75
lack the phenethylamine backbone of DA but still has intrinsic activity. The SAR
of the phenylpiperazines indicated that a hydrogen-bonding group in the meta-position was
preferred for the agonist properties and that the N-substituent could be either a small alkyl or a large
aromatic group. The partial D2 agonists, bifeprunox (12) and pardoprunox (14), are based on the
phenylpiperazine backbone and have a benzoxazolone-group on the aromatic ring with the
hydrogen-bonding functionality in the meta-position. Pardoprunox has a small methyl-group on the
piperazine while bifeprunox has a bulky biphenyl-moiety, yet the intrinsic activity of the two
analogues is similar.76-78
The aripiprazole structure contains a 2,3-dichloro-substituted
phenylpiperazine moiety that has been shown to stabilize the active conformation of the D2 receptor
through a hydrogen-bond between the 3-chloro group and a serine in the active site.79
Recent
studies have also shown that the chlorine-oxygen interaction can be relevant for binding affinities80
albeit not as strong as the hydrogen bonding between a "full" hydrogen donor and acceptor. A
weaker interaction with the receptor is a possible explanation to the fact that although aripiprazole
act as a partial agonist, it has lower intrinsic activity than for example bifeprunox or (–)-3PPP. It
should however be noted that even if a hydrogen-bonding substituent in the meta-position is
positive for intrinsic activity, it is not essential. The π-π interactions are also likely to be important
for the stabilization of the active conformation and the fact that (S)-2-dipropylaminotetralin (S-
DPAT, 28), which lack aromatic substituents, acts as a full DA D2 agonist is a strong indication for
this.56, 58
Moreover, this could explain the intrinsic activity of piribedil (13)81
as well as the fact that
the 2-methoxy analogue of aripiprazole also act as a partial agonist.82
24
1.4.3. MAO Inhibitors. Compounds that bind to and block the effect of MAO can be divided into
reversible or irreversible inhibitors. Furthermore, the inhibitors can be selective for either MAO A
or MAO B or non-selective (having equal effects on both isozymes). As an entity, the MAO
inhibitors (MAOIs) are structurally quite diverse, but there is a distinct separation between
reversible and irreversible inhibitors. While the irreversible inhibitors, for example ipronazid (30,
Figure 8) and selegiline (31, Figure 8), have a functional group (e.g. propargylamine or hydrazine)
that enables covalent binding to the enzyme, the reversible inhibitors lack such moiety. Structural
separations between MAO A and MAO B is less evident, but most reversible MAO A inhibitors
have an aromatic moiety with a basic amino group at 2-4 atoms distance from the ring (e.g.
moclobemide (32, Figure 8) and pirlindole (33, Figure 8). Studies on para-substituted
phenethylamines, benzylamines and amphetamines have shown that the physiochemical properties
of the para-substituent are correlated to the affinity of the two isozymes. Size and electronic
properties have been proposed to mainly impact affinity to MAO A, while the hydrophobicity of the
substituent seems to influence MAO B affinity to a greater extent.
28 29
2726
25
Figure 8. Irreversible MAOIs: iproniazid (30) and selegiline (31). Reversible MAO A
inhibitors moclobemide (32) and pirlindole (33).
1.4.4. Quantitative structure activity relationships (QSARs). SAR is useful when comparing
heterogeneous structural classes with diverse biological activities. There is however a shortcoming
with this method; it assumes that similar molecules have similar activities. This is indeed not
always the case, since many times small differences on the molecular level can have a major impact
on the response. In order to find relationships between a homogenous group of compounds and their
respective activity, quantitative structure activity relationships (QSARs) can instead be applied.
QSAR models attempt to relate chemical structure to biological activity using quantitative
regression by setting the chemical properties of a molecule, or parts thereof (e.g. Hammett constants
of a substituent) against the response variable of a biological activity (e.g. affinity to a receptor).
QSAR modeling generally involves three steps: (1) design of a training set of molecules; (2)
decision on descriptors that are presumed relevant for the correlation between chemical structure
and biological activity; and (3) application of statistical methods that correlate changes in structure
with changes in biological activity. Since in QSAR, the physicochemical properties of chemical
structures as well as biological response are expressed by numbers, a mathematical relationship can
be established between the two. The model can then be used to predict the biological activity of new
chemical structures and is therefore a powerful tool in medicinal chemistry.
Most QSAR models in the field are based on in vitro data as the biological response, or more
specifically, binding affinities to one or many receptors. It has been a general resistance towards
30
33
32
31
26
using in vivo data in QSAR modeling, mostly derived from a skeptic view on the response obtained
from a complex biological system such as a living animal. The data from an in vivo experiment is
often linked to several different aspects of pharmacology, pharmacodynamics and
pharmacokinetics, and therefore each specific contribution can be difficult to interpret. However,
the sum of these aspects for the most part holds very valuable information and an in vivo response
can even be superior to in vitro data in a QSAR model.
1.4.5. Drug Design. In drug design the knowledge of biological targets, usually proteins and
enzymes in pathways that are related to a particular disease state, is used to find new drugs that
affect these targets in a specific way. There are many different techniques that can be used to obtain
this knowledge. The application of X-ray crystallography and NMR spectroscopic methods can
resolve the structure of proteins to a very high resolution, making it possible to determine its 3D-
structure. This information can in turn provide valuable insight into the optimization of the
molecular interactions of a drug-target complex to achieve potency and selectivity of a drug
candidate. However, in order to acquire the 3D-structure of a target protein, it has to be in a
crystalline form and many biological targets are extremely difficult to crystallize. Especially the
trans-membrane proteins have been problematic in this aspect, the main reason being the
amphipathic nature of their surface. Instead computerized modeling, using the amino acid sequence
of the target protein together with known 3D geometrical shape of homologue proteins, can be
applied.
The 3D-structures of both MAO A and MAO B have been determined by X-ray crystallography
with several different ligands83-86
and these structures have been used in the development of novel
classes of MAO inhibitors.87-89
DA D2, on the other hand, has not yet been successfully crystallized,
but molecular modeling based on the 3D structure of the closely related DA D372
and β2
adrenergic90, 91
receptors has provided a better understanding of the ligand-receptor interactions in
this class.79, 92, 93
These studies have revealed that Asp-114 on the third transmembrane helix (TM3)
most likely forms of a salt bridge with the protonated nitrogen of DA and that serine residues in
TM5 (Ser-193, Ser-194 and Ser-197) interact with the catechol function through hydrogen bonding
(Figure 9).94-99
More recent publications have also shown that His-393 on TM6 can form hydrogen
bonds with the catechol or other hydrogen bonding groups of dopaminergic ligands.92, 100
In
addition, Phe-110, Met-117, Cys-118 (TM3), Phe-164 (TM4), Phe-189, Val-190 (TM5), Trp-386,
Phe-389, Phe-390, and His-394 (TM6) contribute to the stabilization of the drug-receptor complex
27
via hydrophobic interactions.92, 100
Ligand interactions with two amino acids, Ile-184 and Asn-186,
in the second extracellular loop (EC2) have also shown to be important (Figure 9).92, 101
It has been
proposed that in the activation phase of GPCRs, TM6 undergoes a translational or rotational
movement, and that the interaction with an agonist facilitates this movement.102-105
In line with this
proposal, Goddard et al. (2007) speculated that DA D2 agonists interact with TM3 (Asp-114) and
TM5 (Ser-193 and Ser-197) by pulling them closer together in the active state, allowing the flexible
motion of TM6.106
An antagonist (such as haloperidol) instead interacts strongly with TM3 and
TM6 (having minimal contact with TM5), thus preventing such movement.99, 106
Figure 9. Schematic view of the interactions between the full agonist (R)-2-OH-NPA and the DA D2
receptor in a homology model by Malo et al.92
Amino acids in purple are polar, while green residues
are hydrophobic. The blue shades indicate ligand–receptor solvent accessibility.
28
29
2. AIMS
This work is a part of a research project aimed at finding novel dopaminergic ligands with
beneficial effects in several neurological and psychiatric disorders. The discovery and mechanism
of action of the dopaminergic stabilizer pridopidine (ACR16, Huntexil®, 16), currently being
developed for Huntington's disease, are included. In addition, the QSARs of mono-substituted 4-
phenylpiperidines/-piperazines have been investigated and correlations between the in vivo and in
vitro profile of compounds in this structural class has been established.
30
31
3. CHEMISTRY (Papers I, II and III)
The compounds included in this work have been synthesized by various methods described in the
literature. Alkylation of commercially available phenylpiperazines/-piperidines using standard
conditions (Scheme 1) produced the bulk of target compounds. Other methods were applied when
the desired starting material was unavailable, and these methods are shown in separate sections.
Scheme 1
a Reagents and conditions: (a) PrI or BnBr, K2CO3, CH3CN, ∆.
3.1. Original Synthetic Route to Pridopidine (Paper I)
Pridopidine (16), or ACR16 as the compound was first named, has recently been developed for
large scale manufacturing and is currently being synthesized with an optimized synthetic route.
However, the first synthesis of pridopidine/ACR16 was performed by a different route (Scheme 2,
R=Pr). In the first step of seven in total, 1-bromo-3-methylthiobenzene was treated with n-
butyllithium and quenched with 1-Boc-4-piperidone to yield 34. Subsequent treatment with
trifluoroacetic acid (TFA) in a solution of DCM led to both deprotection and dehydroxylation,
producing 35 in excellent yield. It is well known in the trait that sulfides contaminate the palladium
of the Pd/C-catalyst used in H2-mediated reductions,107
and therefore the sulfide had to be oxidized
to the corresponding sulfone prior to the reduction step. Attempts to oxidize 35 directly with m-
chloroperbenzoic acid (m-CPBA) did however lead to simultaneous oxidation of the
tetrahydropyridine-ring along with the thiomethyl-group, producing the undesired 4-[3-
(methylsulfonyl)phenyl]pyridine. In order to avoid this side-reaction, 35 was first protected by the
addition of methylchloroformate to afford the carbamate 36, after which quantitative oxidization by
m-CPBA to the corresponding sulfone 37 was possible. 37 was then easily reduced with catalytic
X = N, CH
R' = n-Pr, Bn
R = H, OMe, SO2Me, CN, Me, Cl, OH, CF3, COMe, Ot-Bu
a
32
hydrogenation (Pd/C), affording the piperidine-derivative 38 in good yield. After the deprotection
of 38 with aqueous HCl (8 M), the secondary amine 39 was alkylated with 1-iodopropane, affording
pridopidine/ACR16 (16) (Scheme 2). The corresponding benzyl-analogue (40) was obtained by
alkylation of 39 with benzylbromide. In addition, the preparation of 4-(3-
isopropylsulfonylphenyl)piperidine (87) followed the same synthetic route.
Scheme 2
a Reagents and conditions: (a) n-butyllithium, 1-Boc-4-piperidone, THF; (b) trifluoroacetic acid, CH2Cl2, ∆;
(c) triethylamine, methylchloroformate, CH2Cl2; (d) m-CPBA, CH2Cl2; (e) Pd/C, H2, MeOH, HCl; (f) HCl,
EtOH, ∆; (g) PrI or BnBr, K2CO3, CH3CN,
34 35 36
37 38
39
16 R=Pr
40 R=Bn
g
a b c
de f
33
3.2. Suzuki Cross Coupling between Phenylbromides and 1-Pyridyl-4-boronic acid (Paper III)
The Suzuki cross coupling is a palladium catalyzed cross-coupling reaction between organic halides
and organoboron compounds that leads to the formation of carbon-carbon bonds.108-110
The
mechanism of the Suzuki reaction has been studied extensively in order to fully optimize the
reaction conditions (Figure 10).111
The first step is an oxidative addition of palladium to the halide
(I) which forms an organo-palladium complex (II). Further reaction with the required base (e.g.
Na2CO3, K3PO4) gives an intermediate (III), which via transmetalation with the boronate complex
(V) forms another organo-palladium species (VII). Reductive elimination yields the desired product
(VIII) and restores the original palladium catalyst (IX) for further use.
Figure 10. The proposed mechanism for the Suzuki cross coupling reaction.
In the cases were the desired phenylpiperidine starting material was commercially unavailable and
lithiation or Grignard reaction of the phenylbromide was inapplicable (see Scheme 2), the desired
phenylpiperidines were acquired through Suzuki cross-coupling of the substituted arylbromides
and 4-pyridineboronic acid, followed by reduction of the pyridine ring (Scheme 2).
4-[3-(Trifluoromethylsulfonyl)phenyl]pyrididine (41), 4-[3-(4-pyridyl)phenyl]morpholine (42) , 4-
(3-cyclopentylsulfonylphenyl)pyridine (43) and 4-(4-Methylsulfonylphenyl)pyridine (44) were all
prepared through Suzuki-coupling, but only the pyridine ring of 41 could be reduced directly by
platina-mediated catalytic hydrogenation.112
For the other substrates this reaction was unsuccessful
and instead quarterisation of the pyridine nitrogen by heating with 1-iodopropane preceded the
34
reduction.113
Thus, the desired target compounds 4-(3-cyclopentylsulfonylphenyl)-1-
propylpiperidine (46), 4-[3-(1-propyl-4-piperidyl)phenyl]morpholine (47) and 4-(4-
methylsulfonylphenyl)-1-propylpiperidine (48) were obtained from the reduction step, while a
subsequent N-propylation produced 1-propyl-4-[3-(trifluoromethylsulfonyl)phenyl]piperidine (45).
Scheme 3
a Reagents and conditions: (a) pyridyl-4-boronic acid, Na2CO3, Pd(PPh3)4, toluene/EtOH, ∆; (b) PtO2,
H2, MeOH, konc HCl; (c) PrI, K2CO3, CH3CN, ∆; (d) PrI, ∆; (e) PtO2, H2, MeOH, konc HCl.
3.3. Buchwald-Hartwig Cross Coupling between Phenylbromides and Piperazines (Paper III)
All ortho- and para-substituted, and most meta-substituted, phenylpiperazines included in the data
set could be obtained from commercially available starting materials via N-alkylation (Scheme 1).
However, in order to obtain 1-(3-methylsulfonylphenyl)-4-propylpiperazine (49), 4-benzyl-1-(3-
methylsulfonylphenyl)-piperazine (50) and 1-[3-(benzenesulfonyl)phenyl]piperazine (51), the
corresponding phenylpiperazines had to be synthesized from the phenyl bromides and piperazine
using the Buchwald-Hartwig cross coupling reaction114, 115
. This is a C–N palladium-catalyzed
cross-coupling reaction where the following general mechanism has been proposed:
b, c
45
R=3-SO2CF3, 3-morpholine,
3-SO2cPe, 4-SO2Me
41 R=3-SO2CF3
42 R=3-morpholine
43 R=3-SO2cPe
44 R=4-SO2Me
46 R=3-SO2cPe
47 R=3-morpholine
48 R=4-SO2Me
d, e
a
35
Figure 11. The proposed mechanism for the Buchwald-Hartwig cross coupling reaction.
Bidentate ligands are often used in these reactions to improve the yield, minimize the use of catalyst
and shorten the reaction time.114, 115
1-Bromo-3-(methylsulfonyl)benzene and 1-(benzenesulfonyl)-
3-bromo-benzene were coupled with piperazine using Pd2(dba)3 and rac-BINAP in refluxing
toluene for 15h (Scheme 3). For chelating ligands, oxidative addition occurs directly from the
ligand-palladium complex forming intermediate I (Figure 11). Deprotonation by base followed by
amine ligation produces the palladium amide (II). This key intermediate reductively eliminates to
produce the product (III) and regenerate the catalyst. β-Hydride elimination from intermediate II is
avoided by the chelating phosphine, producing a 4-coordinate species which hinder the side
reaction. The yields were 49% and 87%, respectively, without optimizations.
Scheme 4
aReagents and conditions: (a) piperazine, NaOt-Bu, Pd2(dba)3, rac-BINAP, toluene, ∆; (b)
PrI or BnBr, K2CO3, CH3CN, ∆.
R=Me, Ph 49 R=Me, R'=Pr
50 R=Me, R'=Bn
51 R=Ph, R'=Pr
a, b
36
3.4 Conversion of Functional Groups
3.4.1 Aniline to Morpholine (Paper II). The commercially available 4-(4-piperidyl)aniline was
used to prepare the desired para-morpholine compound. After N-alkylation with 1-iodopropane, a
ring-closing reaction around the aniline nitrogen was achieved by a microwave assisted nucleophilic
substitution using bis(2-chloroethyl)ether in DMF.116
Thus, 4-[4-(1-propyl-4-
piperidyl)phenyl]morpholine (52) was obtained through a 2-step synthesis in an overall yield of
63% (Scheme 5).
Scheme 5
aReagents and conditions: (a) PrI, K2CO3, CH3CN, ∆; (b) bis(2-chloroethyl)ether, DMF, MW.
3.4.2 Phenols to Mesylates and Triflates (Paper III). The mesylate and triflate groups are often
used as leaving groups in aromatic substitution reactions but they can also be used in biologically
active compounds and were found by Sonesson et al. to have beneficial properties in both the 3-
phenylpiperidine and aminotetraline series.117
The transformation from the corresponding phenols
was achieved by addition of triflic anhydride or mesylchloride, respectively, in the presence of
triethylamine (Scheme 6).118, 119
52
a, b
37
Scheme 6
a Reagents and conditions: (a) HBr (48%), ∆; (b) NEt3, CH3SO2Cl or (CF3SO2)2O, CH2Cl2.
3.4.3 Triflate to Nitrile (Paper III). In the 3-phenylpiperidine series, Sonesson et al.117
provided a
convenient route to the cyano-analogue from the partial agonist (-)-3-(3-hydroxyphenyl)-1-propylpiperidine
((-)-3-PPP). The same route was also used to obtain the meta-cyano compound in the 4-phenylpiperidine
series. Starting from the triflate (63), palladium catalyzed carbonylation120
using carbon monoxide and
methanol furnished the methyl ester (66). The ester was converted to an amide (67) via a one-step reaction
using formamide and sodium methoxide in DMF.121
The target compound, 3-(4-propylpiperazin-1-
yl)benzonitrile (68), was then obtained through a dehydration of the amide group by phosphorous
oxychloride in DMF122
(Scheme 7).
53 X=N
54 X=CH
55 X=N
56 X=CH
b
a
55 X=N, R1/R2=H, R3=OH
57 X=N, R1/R3=H, R2=OH
58 X=CH, R1/R3=H, R2=OH
59 X=CH, R1=OH, R2/R3=H
60 X=N, R1=OH, R2/R3=H
61 X=N, R1/R3=H, R2=OSO2Me
62 X=N, R1/R3=H, R2=OSO2CF3
63 X=CH, R1/R3=H, R2=OSO2CF3
64 X=CH, R1=OSO2CF3, R2/R3=H
65 X=N, R1/R2=H, R3=OSO2CF3
38
Scheme 7
a Reagents and conditions: (a) Pd(OAc)2/dppp, CO(g), NEt3, MeOH; (b) HCONH2, NaOMe, DMF; (c)
POCl3, DMF.
3.4.4 Phenols to Alkoxy-groups (Paper II and III). Two different alkoxy compounds were
synthesized from the corresponding phenols. The iso-propoxy derivate (69) was produced by
reaction of the 3-hydroxyphenylpiperidine (58) with NaH in DMF and quenching with 2-
iodopropane. Refluxing the para-isomer (56) in acetonitrile with a weak base (K2CO3) and n-
butylbromide produced the n-butoxy analogue (70) (Scheme 8).
Scheme 8
a Reagents and conditions: (a) NaH, i-PrI, DMF; (b) n-BuBr, K2CO3, CHCN.
c
63 66 67
68
b a
a or b
56 R1=H, R2=OH
58 R1=OH, R2=H69 R1=Oi-Pr, R2=H
70 R1=H, R2=On-Bu
39
4. Pharmacology
4.1 Methods
The target compounds were tested both in vivo and in vitro in different pharmacological assays. The
in vivo models were used to investigate both behaviour and neurochemical effects in freely moving
rats while the in vitro models were used to measure the binding affinities to the DA D2 receptor and
MAO enzymes.
4.1.1. In vitro models. The DOPAC levels produced by a pharmaceutically active compound can be
linked to a number of different targets and as previously mentioned two of these targets are the DA
D2 receptor and the MAO A enzyme. We therefore measured the affinity to these targets for a
subset of compounds chosen to provide as much information about the in vitro SAR as possible. In
addition to pure affinity, the level of intrinsic activity at the D2 receptors is also a determinant for
the DOPAC levels. Partial D2 agonists in general produce less DOPAC than an antagonist at a dose
where maximal effects for both are achieved (see Figure 12). The intrinsic activity was measured in
a functional assay for a few compounds, but the effect in an in vitro model is not necessarily the
same as in the living system. The efficacy data produced in the D2L-Gαqi5 HEK293 cells can
therefore differ from the effects observed in vivo. Another indicator of the agonistic property of a
compound is the ratio between the propensity to displace agonists rather than antagonists from the
receptor. These two assays have been denoted D2High
and D2Low
, where high is the active state and
low the inactive state of the receptor. The same compounds that were examined for intrinsic activity
were also investigated in the D2High
and D2Low
binding affinity assays and the ratios
(Ki(D2Low
)/Ki(D2High
)) from these studies clearly showed that the included compounds were more
prone to displace an agonist than an antagonist. This ratio has also been used as a quantitative
measurement and strong correlations to the results from both in vitro and in vivo assays of intrinsic
activity have been shown.123, 124
In addition, the affinity to MAO B was investigated for the para-substituted compounds in order
to clarify which physicochemical properties of the substituent that was important for interaction
with the respective isozyme. In agreement with previous observations6, we also found that affinity
to MAO B alone was not a contributing factor to the DOPAC levels in the rat.
40
4.1.2. In vivo models. The level of DOPAC in different parts of the brain has been used as a
measurement of the synthesis and turnover of DA. Striatum is the part of the brain that has the
strongest correlation to behaviour and DA is the main neurotransmitter affecting locomotor activity.
Therefore the level of DOPAC in striatum was the biomarker of choice for our in vivo models. Male
Sprague-Dawley rats from B&K Scanbur (Sollentuna, Sweden) or Charles River (Köln, Germany)
were used and five groups of animals, four animals per group, where dosed with either saline
(control) or the test substance in escalating doses (usually up to a 100 μmol/kg). The behaviour was
recorded using motility meters125
and the distance travelled was used as a measurement of the rats
activity. The rats were decapitated 1h after the injection and the effect of the target compounds on
the levels of DOPAC was measured by high-performance liquid chromatography on the
homogenates of the dissected brain. The rats treated with the test compounds were compared to the
saline treated rats in the same experiment (effect expressed as "% of control"), both with regards to
the biochemical markers and the locomotor activity (LMA). Several reference compounds have
been tested in these models in order to compare if the response factors are in agreement with what is
known from the literature. The effects on striatal DOPAC levels following administration of
different D2 ligands were as follows: antagonists (e.g. haloperidol (6)) gave sharp increases, full D2
agonist (e.g. apomorphine) produced decreased levels and partial agonists (e.g. aripiprazole (10)
(Figure 12), (-)-3PPP (11)) yielded varying levels (100 - ~150% of control) of DOPAC. This is in
agreement with previously published results from in vivo studies on rat post mortem
neurochemistry.126-129
The dopaminergic stabilizer pridopidine (16) has effects on DOPAC similar
to an antagonist, although compared to haloperidol, higher doses are required to achieve the
maximal response (Figure 12).
41
Figure 12. Dose-dependent effects of the DA D2 agonist apomorphine, the partial agonists (-)-3PPP,
aripiprazole and 3-(1-benzylpiperidin-4-yl)phenol (29), the antagonist haloperidol and the dopaminergic
stabilizer pridopidine on the DOPAC levels in striatum.
The effects on the locomotor activity by the different ligands were also in accordance with previous
observations. Haloperidol and the partial agonists all produced strong inhibition of the normal
behaviour while apomorphine gave a biphasic effect on locomotor activity (i.e. inhibition at low
doses and stimulation at high doses). The dopaminergic stabilizer pridopidine (16), on the other
hand, had no effect on normal exploratory behaviour and partly habituated rats were even mildly
stimulated.130
Pretreatment with amphetamine has often been used as a model of psychosis and the
induced hyperactivity was blocked by most antipsychotics. However, as seen with the
antagonists/partial agonists, this goes hand in hand with inhibition of the normal exploratory
behaviour. Pridopidine (16) has the ability to counteract the amphetamine induced hyperactivity
without impeding the normal state and this is a central trait of the dopaminergic stabilizers. Analysis
of perfusates collected from microdialysis probes implanted in the striatum of freely moving rats
was used to measure the DOPAC and 3-MT levels during a period of 180 min after administration
of a MAO A inhibitor. The observed effects, with decreases in DOPAC and increased levels of 3-
MT, were in agreement with previous investigations of known MAO A inhibitors.11
All
0
50
100
150
200
250
300
350
400
0.01 0.1 1 10 100 1000
% o
f c
on
tro
l
dose µmol/kg
DOPAC in striatum
42
experiments were carried out in accordance with Swedish animal protection legislation and with the
approval of the local Animal Ethics Committee in Gothenburg
4.2 Results
The results from the different assays are included in Table 1. From the in vivo models, only the
DOPAC levels (presented as % of control) are presented. Additional results can be found in Table
3, Paper I. The in vitro data from the binding assays are all included.
Table 1. In vivo levels of DOPAC and in vitro affinities to D2 and MAO
Comp R' X R Pos
DOPAC,
% of ctrl
± SEMa
pKi
(D2High
)b
pKi
(D2Low
)b
pKi
(MAO A)b
pKi
(MAO B)b
71 n-Pr N H None 181 ± 6 d 6.3
e
4.3d
72 n-Pr CH H None 131 ± 11 d 6.8
e
5.0d
60 n-Pr N OH Ortho 270 ± 23 e
64 n-Pr CH OSO2CF3 Ortho 270 ± 16 e
73 n-Pr N OMe Ortho 370 ± 24 e 7.7
e 7.1 <3.2
e f
74 n-Pr CH OMe Ortho 277 ± 18† †
e
7.9 e
5.6 e
75 n-Pr N SO2Me Ortho 283 ± 16 e 6.2
e
<3.2 e f
76 n-Pr N CN Ortho 313 ± 9†† e
77 n-Pr N Me Ortho 327 ± 16 e
78 n-Pr N Cl Ortho 368 ± 19 e
79 n-Pr CH CF3 Ortho 254 ± 20 e
16 n-Pr CH SO2Me Meta 265 ± 10c 5.1
c 4.5
c
29 Bn N OH Meta 108 ± 4 c 8.3
c 7.0
c
40 Bn CH SO2Me Meta 310 ± 16 ††c
6.4 c 6.1
c
45 n-Pr CH SO2CF3 Meta 258 ± 15 e
46 n-Pr CH SO2c-Pe Meta 170 ± 10 e 5.4
e
<3.2 e f
47 n-Pr CH morph Meta 105 ± 7 e
49 n-Pr N SO2Me Meta 310 ± 16††c
6.2c 5.9
c 3.9
e
50 Bn N SO2Me Meta 248 ± 10 c 6.4
c 5.7
c
51 n-Pr N SO2Ph Meta 152 ± 7 e
57 n-Pr N OH Meta 260 ± 12††c
7.2c 6.1
c <3.2
e f
58 n-Pr CH OH Meta 107 ± 4†c
6.5c 5.6
c
61 n-Pr N OSO2Me Meta 254 ± 18† e
62 n-Pr N OSO2CF3 Meta 285 ± 12 e
63 n-Pr CH OSO2CF3 Meta 241 ± 6 e
Cont.
43
Comp R' X R Pos
DOPAC,
% of ctrl
± SEMa
pKi
(D2High
)b
pKi
(D2Low
)b
pKi
(MAO A)b
pKi
(MAO B)b
68 n-Pr CH CN Meta 275 ± 10 e
69 n-Pr CH Oi-Pr Meta 112 ± 6 e
80 n-Pr N OMe Meta 255 ± 16 e 6.5
e
4.8e
81 n-Pr CH OMe Meta 140 ± 8 e 5.8
e
4.7 e
82 n-Pr N CN Meta 314 ± 17 e 6.6
e
<3.2 e f
83 n-Pr N CF3 Meta 315 ± 15† e
84 n-Pr CH CF3 Meta 260 ± 9 e 6.7
e
3.9 e
85 n-Pr N Cl Meta 250 ± 9 e
86 n-Pr N COMe Meta 221 ± 9 e
87 n-Pr CH Me Meta 115 ± 7 e
88 n-Pr CH SO2i-Pr Meta 205 ± 9 e
89 n-Pr CH Ot-Bu Meta 196 ± 9 e
90 Bn CH OH Meta 317 ± 13††
c
7.4 c 6.5
c
48 n-Pr CH SO2Me Para 94 ± 5† d
<3.2d f
3.23 d
52 n-Pr CH morph Para 38 ± 2 d
5.9d 4.89
d
53 n-Pr N OMe Para 72 ± 3 d 5.2
e
5.9d 3.23
d
54 n-Pr CH OMe Para 22 ± 1 d 4.6
e
6.6d 3.66
d
65 n-Pr N OSO2CF3 Para 122 ± 3 d
4.8d 7.48
d
70 n-Pr CH On-Bu Para 41 ± 2 d
6.4d 5.8
d
91 n-Pr CH CN Para 94 ± 2 d
4.0d 3.23
d
92 n-Pr CH Cl Para 68 ± 4 d 6.0
e
5.8d 4.42
d
93 n-Pr CH CF3 Para 86 ± 5 d
5.2d 4.89
d
aPost-mortem biochemistry of levels of DOPAC in the striatum compared to saline control (n = 4) at 1h after
administration of 100, †50 or
††33
μmol/kg of test compound (the dose where maximum DOPAC response is
produced). bNegative logarithm of binding affinities (apparent Ki) to human recombinant HEK-293 cells with
[3H]7-OH-DPAT as ligand for D2
High and [
3H]spiperone as ligand for D2
Low and to rat cerebral cortex cells
with [3H]Ro 41-1049 as ligand for MAO A and Ro 16-6491 for MAO B.
cData from paper I.
dData from
paper II. eData from paper III.
fC50 higher than 1 mM = Ki higher than 0.58 mM.
4.2.1. In Vitro Binding: D2High
, D2Low
, MAO A and MAO B and Intrinsic Activity at D2
Receptors (Paper I-III). The starting point for the development of the new dopaminergic ligands
in the 4-phenylpiperidine/-piperazine series was the partial agonist 3-(1-benzylpiperidin-4-yl)phenol
(29) previously reported by Mewshaw et al.75, 131
This compound has a high preference for
displacing agonist over antagonist ligands at the D2 receptor (i.e. high Ki(D2Low
)/Ki(D2High
) ratio)
and has therefore been classified as a potential partial agonist. In analogy with the development of
S-(-)-OSU6162 (15) from the partial agonist (-)-3-PPP (11), we wanted to modify the key elements
of 29 that are responsible for its intrinsic activity in order to produce compounds with little or no
44
intrinsic activity but with a sustained agonist-like interaction with the receptor. The portions of the
molecule that we speculated as being most likely to contribute to stabilization of the active
conformation were the phenol group, the piperazine and the large, aromatic N-alkyl group. Binding
affinities of 29 to D2Low
and D2High
(Table 1) in our hands confirmed Mewshaw's results and in the
functional assay 29 also showed a relatively high intrinsic activity (Table 2 in paper I), verifying
that this compound indeed is a partial D2 agonist. Any modification of the key elements in the
structure led to a loss of efficacy in the functional assay while the Ki(D2Low
)/Ki(D2High
) ratio, albeit
significantly lower than for 29, stayed ≥ 2, regardless of which portions were exchanged. However,
in vitro assays measuring intrinsic activity can show varying results depending on which model that
is used and it can therefore be difficult to determine the intrinsic activity observed in vivo with such
assays.67, 132
Another interesting aspect of the interaction between the receptor and the ligand is the receptor
kinetics. Many recent publications have presented fast dissociation from the D2 receptor as a
possible link to atypicality for the DA mediated antipsychotics used in the clinic.54, 61, 133, 134
In a
model using multiple washes of ligand-pretreated D2 cells in order to detect how long it takes for the
cell to regain responsiveness to DA, all tested compounds in this structural class displayed fast
dissociation from the receptor (shown in Figure 2 of Paper I and as reported by Dyhring et al.62
).
This competitive interaction means that the effect of normal DA surges is less affected, which
according to the theory would lead to an improved side effect profile. In sharp contrast, haloperidol
had a slow dissociation, indicating a non-competitive antagonism where the inactive conformation
of the DA receptor is stabilized and the responsiveness is diminished for a long time.
These intriguing results led us to a further exploration of how substitution of the phenyl ring
affects the biological response. In order to investigate the effects of aromatic substitution and type
of heterocycle, the N-alkyl moiety was set to 1-propyl. The substituent in mono-substituted
phenylpiperidines/-piperazines can be located in three different positions; ortho, meta or para in
relation to the heterocycle. All positions were investigated and the effect on the affinity, primarily
to the D2 receptor, was determined for a selected subgroup. Three compounds with substituents in
the ortho-position were tested for their affinity to D2 and the electron-donating methoxy group
yielded a higher affinity than the corresponding electron-withdrawing methylsulfone. The meta-
substituted subclass showed no such differences and the only compound having somewhat higher
affinity to the D2 receptor was the phenol-piperazine (57, Table 1). For compounds with
substituents in the para-position, the D2 receptor affinity was lower than for the corresponding
45
ortho- and meta-analogues and it seems that this position is not preferred for the interaction with
this receptor.
However, affinity and intrinsic activity at D2 was not sufficient to explain the observed
neurochemical effects for all compounds and especially the para-substituted subclass differed
greatly in their in vivo response compared to the other two positions. Their effects on the DOPAC
levels led us to suspect that they were actually MAO inhibitors rather than D2 ligands, and therefore
the affinity to the two MAO isozymes was also measured. The affinity, primarily to MAO A, for the
para-substituted compounds confirmed our hypothesis and moreover a strong correlation between
the electronic properties of the substituent and the affinity to MAO A was observed. Affinity to
MAO B was also apparent for a few of these compounds, but the correlation to the in vivo effects
were absent in this class. Furthermore, in addition to the para-substituted class, MAO A affinity
could be detected for the ortho- and meta-substituted compounds as well, albeit not as high and
only secondary to the D2 affinity. MAO A affinity was only measured for a few ortho- and meta-
substituted compounds but the connection between electronic properties of the substituent and
affinity to MAO A seems to be highly relevant in these positions as well. In order to explore which
structural motifs that influence the in vitro effects, quantitative models with physicochemical
descriptors were produced and these are addressed separately.
The D2 receptor and MAO A are the targets with the most abundant impact on the DOPAC
response in the brain. However, other targets are involved in the process of synthesis, storage,
release, reuptake and metabolism of DA. COMT is involved in the metabolism of DA but in
complete contrast to MAO A, inhibition of this enzyme leads to increased levels of DOPAC and
decreased levels of 3-MT. However, all of the known COMT-inhibitors (e.g. tolcapone,
entacapone) are structurally dissimilar to our compounds and it is therefore highly unlikely that this
mechanism is involved in the observed in vivo effects. Dopamine and norepinephrine transporter
(DAT and NAT) inhibitors also affect the DOPAC levels in striatum, albeit in general to a much
lesser degree than compounds acting on the D2 receptor or MAO A. A few of the compounds in the
data set have been investigated in both DAT and NAT assays where the % displacement at 1 μM
was determined (Appendix A). The only compounds displaying any relevant affinity are the para-
susbtituted compounds 91 and 92, which have 22% displacement for NET and 36% displacement
for DAT, respectively. The limited impact on DOPAC and low affinity of our compounds makes it
unlikely that these targets are of any major importance for the models. As mentioned in the
introduction, the sequence homology between the TM regions of DA D2 and DA D3 receptors are
46
~75%, making subtype-selective ligands difficult to obtain. Even though we have no data to support
it, the compounds presented here are most likely affecting the D3 receptor very much the same way
they affect D2. However, since D3-ligands have no relevant effect on the DOPAC levels, this
interaction is insignificant for our correlations.24
4.2.2. In Vivo Effects: Neurochemistry and Locomotor Activity. In agreement with the in vitro
effects, 29 displayed an in vivo profile that can be directly related to partial agonism. The DOPAC
levels were unchanged within the whole dose range, and this can be attributed to a perfect balance
of intrinsic activity at the DA releasing presynaptic receptors. As a full agonist produces a
significant decrease in DOPAC levels compared to the untreated animals, partial agonists yield
different DOPAC responses dependent on the level of intrinsic activity. In the case of 29 it is
therefore likely that the activation of the presynaptic receptors is just enough to keep the release of
DA at a rate comparable to the unaffected system. At the same time, this compound induces a
strong inhibition of the locomotor activity, which indicates that the normal postsynaptic effect of
DA is blocked and the agonist property of 29 is too low to stimulate the behaviour.
When modifying 29 the levels of DOPAC tended to increase dramatically, and as the binding
affinities simultaneously were diminished (29 has the highest affinity to D2 of all tested 4-
phenylpiperidines/-piperazines), decreased intrinsic activity is the likely explanation. However, in
contrary to the intrinsic activity data from the in vitro efficacy model, a few of the compounds in
this subgroup could be expected to have weak intrinsic activity in vivo. For example, 57 has a
maximum DOPAC response of 260% of control and this level is reached at 33 μmol/kg (higher
dose does not increase the DOPAC response). This indicates that the presynaptic effects are not
fully antagonistic, despite the lack of intrinsic activity in the in vitro assay. Similar to 29, 57 also
induce an inhibition of the normal behaviour and this is most likely linked to the relatively high
affinity to D2 receptors. In Figure 5 of Paper I a strong correlation between affinity to D2 receptors
and locomotor activity can be observed. The set of compounds included in this correlation are both
D2 receptors antagonists and partial agonists and this indicates that the intrinsic activity, unless very
high, does not affect the behaviour to any relevant degree.
Even if specific compounds are likely to be partial agonists and the in vivo model can reveal
this, it is not a feasible method to use DOPAC levels as an indicator of intrinsic activity on the
whole data set. Firstly, the potency of each compound differs and while some reaches the full effect
at doses below 100 μmol/kg (the highest dose in the standard interval) others are likely to require
47
higher doses in order to reach the maximum possible response. This issue can be exemplified with
16, for which the standard dose interval is not sufficient to achieve maximum DOPAC response and
at a 100 μmol/kg the neurochemical profile could be mistaken for being a product of partial
agonism. When increasing the dose to 300 μmol/kg, higher DOPAC levels, that instead indicate
antagonist effects in vivo, are obtained. For 16 it is likely that 100 μmol/kg is not a sufficient dose
to reach the maximum effect due to the low affinity (Table 1). However, even compounds with high
affinity in vitro may require higher doses to achieve the maximum effect in vivo, since low
bioavailability, poor penetration of the blood-brain barrier etc. can lead to low concentrations of the
compound at the site of action. So unless the maximum DOPAC levels are high enough to rule out
any intrinsic activity at the highest dose tested (e.g. 78) or the maximum effect is produced at a dose
below 100 μmol/kg (e.g. 57), the DOPAC response can not by itself be used as an indicator for
intrinsic activity. Moreover, the affinity and efficacy at D2 receptors are not the only determining
factors for the DOPAC response and other mechanisms must be considered. In the para-substituted
class sharp decreases in DOPAC levels was observed and this was concluded to be connected to
their inhibitory effects on MAO A rather than the effect on D2 receptors. As it has become clear that
substitution in the ortho- and meta-position also can lead to inhibition of MAO A, and thus a
depressing effect on the DOPAC levels, it is most likely that we have two separate mechanisms
producing the in vivo response. In order to more thoroughly investigate what mechanisms are
connected to the in vivo response, binding data for both D2 receptors and MAO A was acquired for
a subset of molecules. Using Partial Least Square (PLS) regression135-137
, the pKi values for D2 and
MAO A could be set against the DOPAC levels in a multivariate model and to our surprise a very
strong correlation could be observed between the in vivo and in vitro effects (Figure 13).
48
Figure 13. Relationship between observed versus predicted response in the PLS model of
log(DOPAC) versus pKi(MAO A) and pKi(D2) for compounds in Table 1 that have binding data
from both the D2High
and MAO A assays.
This correlation led us to suspect that D2 antagonism and MAO A inhibition are the dominating
mechanisms behind the in vivo data for this structural class and that intrinsic activity at D2 is
secondary in affecting the DOPAC response.
Moreover, the position and physicochemical character of the substituent as well as choice of
heterocycle is clearly of high relevance to both the in vivo and in vitro response. Although some
SARs can be manifested from the data by qualitative methods, the relatively large data set makes
the task at hand quite demanding. Thus, in order to further explore the effect of different aromatic
substituents in different positions as well as the impact the choice of heterocycle has on the
response, quantitative methods were employed.
75
46
92
54
53
84
8249
57
73
74
71
72
80
81
R² = 0.86591.20
1.40
1.60
1.80
2.00
2.20
2.40
2.60
1.40 1.60 1.80 2.00 2.20 2.40 2.60 2.80
Ob
serv
ed
Predicted
49
5. Quantitative Structure Activity Relationships (QSARs)
The connection between structural motif and biological response in the mono-substituted
phneylpiperidines/-piperazines is not easily interpreted and the use of qualitative descriptors
combined with multivariate calculations is a way to illustrate which properties are related to each
response in an efficient manner. Additionally, these models can be used to predict the response of
new compounds with a desired pharmacological profile within this structural class.
5.1 QSAR models of in vivo and in vitro responses (Paper III)
The position of the aromatic substituent is clearly of great importance for both the in vitro and in
vivo responses and the dataset was built on these premises. In addition, the physicochemical
property of the substituent and the choice of heterocycle also influence the pharmacological effect.
We therefore chose to include the following descriptors:
A qualitative variable (QV) describing position relative to the heterocycle (i.e. none, ortho, meta
and para)
Descriptors for the whole molecule (i.e. clogP and LClogD)
Seven descriptors that together describe the substituent's physicochemical character (i.e. hydrogen
bond donating/-accepting properties (HD and HA), Hammet's electronic constants (σm and σp),
group dipole moment (μR), volume (volR) and lipophilicity (π))
Number of nitrogen atoms in the heterocycle (RingN) which in effect separates piperidines from
piperazines.
QVs are discrete variables that for this model are split into four dummy variables (Rpos = none,
ortho, meta or para) containing group-belongings (coded as 1 for yes and 0 for no). ClogP is a
calculated descriptor that describes the lipophilicity of the whole compound. LClogD is an
experimental descriptor that stems from HPLC retention times at pH 7.4 and therefore combines
lipophilicity and ionization at physiological conditions. The substituent-descriptors are obtained
from the literature (σm, σp and μR), calculated (volR and π) or coded as 1, 0.5 or 0 depending on
their ability to participate in hydrogen bond (HD and HA). Recently published results80
indicate that
chlorine has some hydrogen accepting capacity and it is therefore set to 0.5.
The chosen descriptors were modelled against the maximum level of DOPAC and the affinity to
MAO A and D2 receptor respectively, using PLS regression.135-137
The DOPAC model have the
50
largest number of observations (43) since in vivo data is present for all compounds in the data set.
This yields a two component model with a R2Y of 0.85 and a Q
2 of 0.78 which indicate good
quality and high predictivity, especially for a model based on in vivo data.
The QSAR models with the in vitro binding affinities to MAO A and D2 receptors, respectively,
as response have fewer observations than the in vivo model (21 for MAO A and 17 for D2).
However, the number of observations still supersedes the number of descriptors which is usually
desirable in order to avoid over-interpretation. For MAO A, a one component PLS regression model
with R2Y = 0.68 and Q
2 = 0.53 was obtained while the D2 model had two components and R
2Y =
0.82 and Q2 = 0.54. Comparing the values of Q
2, it becomes obvious that the in vitro models are
less predictive than the DOPAC model. This may be related to the previous assumption, that the in
vivo responses of these compounds are primarily a result of the combined in vitro binding affinities
to MAO A and D2 receptors. The DOPAC model can therefore be said to describe both the in vitro
effects simultaneously, which in combination with the larger set of in vivo observations would help
produce a better model.
The coefficient plots of the predictive components are a convenient way to interpret the QSAR
models and get an overview of which structural elements that are important for each response. The
plots show which descriptors have the highest influence on the response as well as if the influence
is positively or negatively correlated to the effect. A general rule of thumb is that a descriptor that is
positive for D2 is also positive for DOPAC while a descriptor that is positive for MAO A is
negative for DOPAC and vice versa. Thus, the sum of the impact a descriptor has on D2 and MAO
A is generally reflected in the impact the same descriptor has on DOPAC (Figure 14).
The position of the substituent is of great importance in all models. The ortho- and meta-
position correlates positively with the DOPAC levels while a negative correlation is observed for
the para-position (Figure 14). The opposite is true for MAO A affinity, where substitution in the
para-position is essential for high affinity while ortho and meta have a negative impact. The
position-effects in the D2 model are similar to those of the DOPAC model, but the meta-position has
only minimal influence on this response. Taken together, this explains how the location of the
aromatic substituent is connected to the in vivo and in vitro effects and how these effects are related
to each other. However, the response is also influenced by the physicochemical character of the
substituent and the coefficient plots can help us understand these correlations.
The electronic components (σm, σp and μR) show that electron-withdrawing properties are
positively correlated to the DOPAC response, negatively correlated to the MAO A affinity and of
51
minor importance to the affinity to D2 receptors (Figure 14). This indicates that compounds with
electron withdrawing groups have lower MAO A affinities, and with that higher DOPAC levels,
compared to the compounds substituted with electron donating groups.
The size of the substituent (volR) affects the DOPAC response negatively and according to the
coefficient plots from the in vitro models, this is related to a diminished binding to D2. Larger
groups are not well accepted according to the DOPAC response and a poor fit in the active site of
the D2 receptor is a possible explanation. The phenylsulfone (51) moiety is predicted to produce
high DOPAC levels, probably linked to the fact that it is a piperazine-analogue with electron-
withdrawing properties of the meta-substituent (both are positive for DOPAC increase). However,
the observed response is much weaker than predicted (Figure 3, Paper III) and it is likely that this
effect is connected to the size of the substituent.
Hydrogen donating/accepting properties are not a major determinant for the most part, but in the
D2 model the hydrogen donating groups yield high affinity. This can be directly related to the 3-
hydroxyl group, which in general makes good substrates of dopamine-like compounds. However,
the influence of HD on DOPAC is not in proportion to the influence on D2 and this deviation is a
further indication that the phenol contributes to intrinsic activity.
Lipophilicity (π and clogP) has a substantial positive impact on the MAO A affinity and no
relevant influence on D2 affinity. Following the general relationship, this would lead to lipophilicity
having a negative correlation to DOPAC and yet the DOPAC response is not affected by this
property. It is a common phenomenon that highly lipophilic compounds have better affinity to
different targets in vitro than more polar analogues. However, this is not always relevant to the
effect these compounds have in a living system. Plasma protein binding and the propensity to be
metabolized by liver enzymes are only two examples of in vivo related mechanisms that may
counteract the overall effect of a lipophilic compound, even if the interaction with the target itself is
optimal. However, what abolishes the effect of lipophilicity on the DOPAC response in this case
remains to be investigated.
The number of nitrogen atoms in the ring shows a positive correlation to DOPAC and these
effects are related to the impact the choice of heterocycle has on both MAO A and D2 affinity.
Piperazines have lower affinity to MAO A than the piperidines which are manifested by the
negative bar in the coefficient plot from the MAO A model (Figure 14). The opposite is true for D2
were piperazines tend to have higher affinity than the piperidines. Thus the negative correlation
between MAO A and DOPAC together with the positive correlation between D2 and DOPAC make
52
the in vitro effects of this property additive towards the in vivo response. The experimental
descriptor LClogD is also highly affected by the choice of heterocycle. The retention time from
HPLC which this descriptor is based on is to a large extent affected by the level of ionization of the
tested compound. Piperazines and piperidines have different pKa values and the ionization at
physiological pH therefore differs, subsequently leading to variations in the retention time.
Piperazines have lower pKa than the corresponding piperidines and are therefore less ionized at pH
7.4. This in turn leads to longer retention-times which are expressed as higher LClogD-values
(method for calculating LClogD is described in the method-section of Papers II and III). Albeit
highly influential, the level of ionization is only in part determining the retention-time in the HPLC.
Lipophilicity of the compound is also a major contributor and since the column used in the method
is llipophilic (reversed phase), more lipophilic compounds yields higher values. LClogD can
therefore be said to be the sum of the lipohilicity of a compound and its propensity to be ionized at
physiological pH and these two properties are basically described by clogP and Ring N. This also
become obvious when observing the coefficient plots, where the direction and significance of the
LClogD-descriptor is more or less the sum of clogP and Ring N.
53
Figure 14. PLS coefficient plots of the predictive components from each of the QSAR models with
DOPAC, D2 and MAO A, respectively, as response.
5.2 Development of new electronic descriptors (Paper IV)
The relationship between electronic properties of the substituent and the DOPAC response made us
interested in further investigating these effects. The most common descriptors in QSAR modelling
are the Hammet's constants σm and σp. Although useful in describing basic electron-
withdrawing/donating properties, these descriptors are not developed for explaining the
physicochemical character of substituted aromatics in a biological system but rather the reactivity of
an aromatic carboxylic acid with the substituent located in the meta- (σm) or para- (σp) position. In
addition, the Hammett constants are derived experimentally and therefore values for substituents
that are not tabulated in the literature will be difficult to obtain. On these premises we sought to find
an alternative to the classical constants using quantum mechanical calculations to get descriptors
DOPAC
D2
MAO A
54
that were interpretable, calculable and significant for use in QSAR models. The method used to
calculate these new descriptors is described in the methods section of Paper IV.
The calculated descriptors were assessed in order to reproduce σm, σp and the absolute value of
the group dipole moment (µ) in a PLS regression model. This analysis clearly showed that the two
sets of descriptors are highly correlated (see Figure 4 in Paper IV) and we therefore decided to
exchange the common electronic descriptors in each of the QSAR models for DOPAC, D2 and
MAO A with these new descriptors, while leaving all the other parameters unaffected. The new
models are very similar to the original models in terms of R2Y and Q
2 and the combined plots of
observed versus predicted DOPAC models, with the classical or the new electronic descriptors,
shown in Figure 15 is a good illustration of the existing correlations. In addition, the impact of the
electronic properties in each of the in vitro models was investigated by removing the electronic
descriptors and regenerating the model without them. In the D2 model, the predictivity (Q2) actually
increased when the electronic descriptors were removed, while for the MAO A model a sharp
decrease in Q2 followed the exclusion (see Table 2, Paper IV). These results gave further support to
the previously established theory, that electronic properties are important mainly for the affinity to
MAO A and that this is the main mechanism behind the influence of electronic properties on the
DOPAC response.
Figure 15. The observed versus predicted levels of DOPAC in striatum as log(percent of control). Green:
QSAR based on QM descriptors. Blue: The Pettersson et.al QSAR based on empirical parameters.
1.2
1.4
1.6
1.8
2
2.2
2.4
2.6
1.4 1.6 1.8 2 2.2 2.4 2.6 2.8
Ob
serv
ed
Predicted
55
6. Ligand-Target interactions at MAO A and D2 receptors
The interaction between the para-substituted phenylpiperidines/-piperazines and the MAO A
enzyme was exemplified by compound 54, which was fitted in the active site by means of
molecular modelling based on an X-ray crystal structure of MAO A (Figure 4, Paper II). This model
revealed a hydrophobic pocket in which the aromatic substituent fitted while an interaction between
the methoxy-oxygen and Cys323 further stabilized the complex. The binding pose of 54 is very
similar to the 4-substituted phenethylamines presented by Gallardo-Godoy et al.138
and it is
interesting to compare how substitution in other positions of the aromatic ring affects the MAO A
affinity in the two structural classes. The 2- and 3-position of the phenethylamines are unfavourable
compared to the 4-position, very much like substitution in ortho- or meta-position in the
phenylpiperidines/-piperazines are unfavourable compared to the para-substituted analogues.
Gallardo-Godoy et al. proposed that sterically disfavoured areas, especially where the 3-substituents
are located, led to the diminished affinity. The substituents in the phenethylamine series are
primarily alkoxy-groups and a comparison of positional effects with the methoxy-substituted
phenylpiperidines (74, 81 and 54) reveal that affinity to MAO A follow the same trend in both
structural classes (i.e. para>ortho>meta). The same relationship is however not seen with the
phenylpiperazines, where a methoxy-group in the ortho-position (73) rendered a compound inactive
in the MAO A assay while the corresponding meta-analogue (80) had the same affinity as the
piperidine. Gallardo-Godoys group proposed a π-π stacking interaction between the aromatic ring of
the phenethylamines and Phe208 in the active site of MAO A and thus a possible explanation to the
deviating effects of the phenylpiperazines is a different character of the π-system. Since a lone pair
on the anilinic nitrogen is partly delocalized, the π-π stacking interaction between the aromatic ring
and the MAO A receptor may be disturbed, leading to a generally weaker interaction. Another
possibility is that the angle between the phenyl and heterocyclic rings are important for the
interaction with MAO A and since these differ in the low-energy conformations of phenylpiperidine
and phenylpiperazine (see below), this could affect the affinity. Regardless of the reason, it is likely
that the phenylpiperidines and phenethylamines interact with the active site of MAO A in a similar
fashion while in the phenylpiperazine class some of these interactions are different.
The interaction between the ligand and the D2 receptor is decisive for both the affinity and
intrinsic activity and it is therefore of interest to elucidate what structural motifs in the
phenylpiperidines/-piperazines that are important for both these properties. We have concluded that
3-(1-benzylpiperidin-4-yl)phenol (29) has high affinity to D2 receptors and intrinsic activity both in
56
vitro and in vivo. The structural properties that we expected to be responsible for these effects are
the phenylic 3-hydroxyl group, the piperazine and the N-benzyl. The 3-hydroxyl group is a mimic
of the catechol in dopamine and therefore an important motif in the interaction with the D2 receptor.
Exchanging this group with a methylsulfon (50) leads to lower affinity to both D2Low
and D2High
, a
major drop in the KiLow
/KiHigh
ratio and a complete loss of intrinsic activity in vitro. It is therefore
safe to say that the phenol in 29 is highly involved in the stabilization of the active conformation of
the D2 receptor. The distance between the aromatic ring and the nitrogen atom of the basic amino
group differ between DA and phenylpiperidines/-piperazines and thus the compounds in our data
set are less "dopamine-like" than compounds based on the phenethylamine backbone (e.g. the 3-
phenylpiperidines described by Sonesson et al.139
). Studies have shown that for the 4-
phenylpiperidines, the most stable conformation is when the piperidine ring and the aromatic ring
are perpendicular to each other, while for phenylpiperazines co-planarity between the piperazine
and aromatic ring is the most stable conformation (due to the sp2 hybridization of the anilinic
nitrogen).131, 140
Rotation from these conformations in order to get a better fit in the receptor costs
energy and such "energy-penalties" are associated with lower affinities and less intrinsic activity.92
It is therefore likely that the angle between the phenyl and piperidine in 90 is less optimal for the
ligand-receptor interaction than it is for the corresponding piperazine (29) and that this is the reason
for the lower affinity and less intrinsic activity of 90. We have also made MMF94S energy
minimization studies141, 142
on the 3-hydroxypiperazine (57) and 3-methylsulfonpiperidine (16) in
order to compare the angle between the aromatic ring and the heterocycle for the low energy
conformations. These studies show that, in accordance with previous studies, the phenyl and
piperazine rings are co-planar while the phenyl and piperidine are perpendicular (Figure 16).
Figure 16. The 3D structures of 16 (left) and 57 (right) in their respective low energy conformation.
57
The piperazines in general have higher affinity to D2 receptors than the corresponding piperidines
and the in vivo effects also reflect this. Therefore the angle between the aromatic ring and the
heterocycle is likely to be important and may suggest that the stable conformation of the piperazine
is more optimal for the interaction with the DA D2 receptors compared to the piperidines. There are
however some deviations from this rule. The unsubstituted and the ortho-methoxy substituted
phenylpiperidines (i.e. 72 and 74, respectively) have higher affinity to D2 receptors than the
corresponding phenylpiperazines (71 and 73, respectively). Lacking substituents in the aromatic
ring (i.e. no substituent in the meta-position that needs to recognize an interaction-point in the
receptor) leaves the hydrophobic interactions as the most important factor for stabilization of the
ligand receptor complex. These interactions are likely to be less sensitive to an optimal
conformation of the piperidine/piperazine which would eliminate the energy-penalty, and thus the
lower affinity, for the phenylpiperidine. In addition, other properties, such as lipophilicity, would
become more important for the affinity and that may be the reason for the more lipophilic piperidine
to bind harder than the corresponding piperazine. In a study by Dijkstra et al.140
, the conformation
of arylpiperidines/-piperazines with substitution in different positions has been studied and it is
obvious that the orientation between the aryl and heterocyclic rings is highly influenced by the
location of the substituent. Ortho-substitution inevitably forces the heterocycle towards a
perpendicular orientation in relation to the aryl, regardless of whether the heterocycle is a piperidine
or piperazine. This means that the ortho-substituted phenylpiperidine/-piperazine all have the same
phenyl-heterocycle conformation and therefore no major difference in affinity to D2 are observed.
The N-alkyl group is also of some importance as exchanging the benzyl in 29 to a propyl-group
(57) led both to a diminished affinity and a loss of intrinsic activity in vitro. The same replacement
for the corresponding piperidines (90 and 58) also led to an attenuated affinity, indicating that the
extra aromatic ring is beneficial for the ligand-receptor interaction in the phenol series. However,
for the methylsulfones, the drop in affinity was not observed for the piperazines (50 and 49)
whereas for the piperidines (40 and 16), the N-alkyl effect was similar to the phenols. This is further
implications that interactions between specific parts of the ligands and the receptor are more or less
important depending on which other interactions are present.
Even if the in vitro model shows no intrinsic activity for the tested N-propyl analogues, the in
vivo data indicate that some of the meta-substituted compounds are likely to act as partial agonists.
Due to the structural resemblance to the ligands modelled in the D3 receptor by Newman et al.79
, we
decided it to be relevant to use this work as a reference for the proposed interactions of the
58
compounds in our data set. However, the interaction between the meta-chloro of 2,3-
dichlorophenylpiperazine and Ser194 (5.43) on TM5 that Newman et al. has claimed to lead to a
stabilization of the active conformation of D3, is depending on the absence of N-alkyl on the
piperazine. With an N-alkyl group present the compounds in this model got twisted in such a way
that the bond between the chlorine and oxygen could not be formed. Yet even with an N-alkyl group
as long as butyl, some intrinsic activity could be detected in the Go BRET assay, indicating that the
receptor was not completely stabilized in the inactive conformation. In the same model, the 2-
methoxyphenylpiperazine could not interact with the serine in a way that led to a stabilization of the
active conformation and subsequently the intrinsic activity was lower than for the corresponding
dichloro-analogue. The homology between D2 and D3 is high with similar 3D conformations, but
some differences have been observed, especially in the extracellular loop regions.68
Since some of
the meta-substituted compounds in our series are thought to act as partial agonists at D2 while the
ortho-substituted compounds all have antagonist profiles, we expect that the ligand-receptor
interaction of our compounds is similar to the Newman model.
Besides the intrinsic activity, the in vivo response is influenced by both the affinity to MAO A
and the potency at D2 receptors and it is therefore hard to decide if a compound acts as a partial
agonist based on the DOPAC levels alone. However, the meta-hydroxyl compounds 57 and 58 are
likely to have intrinsic activity based on their affinity to MAO A/D2 and DOPAC levels (although
58 have only been tested in vivo up to 50 μmol/kg) and 57 also has lower DOPAC than predicted in
the in vivo/in vitro correlation (Figure 13). The hydroxyl-group is both a good hydrogen bond donor
and acceptor and a hydrogen bond to a serine or a histidine residue in the active site, leading to a
stabilization of the active conformation of D2, is therefore likely. And if this is possible for the
meta-hydroxy compounds, other analogues with hydrogen-bonding meta-substituents could also
interact in this manner.
The π-π interactions are an important class of noncovalent ligand−receptor interactions and have
been proposed to be involved in the stabilization of the active conformation of D2.73, 92, 143-145
A
good example of this is (S)-dipropyl-2-aminotetralin (S-DPAT), which lack aromatic substituents
but is still a full DA D2 agonist.56, 58
Furthermore, the electron withdrawing/donating properties of
aromatic substituents are related to the electron density of the aromatic ring, which in turn has an
impact on the proneness of the ring to participate in a π-π interaction.146, 147
In the
phenylpiperidine/-piperazine class, it is possible that the electronic properties of the substituents
affect the ability of the aromatic ring to π-interact with the receptor and thus influence the intrinsic
59
activity. Although the impact of the electronic properties on the DOPAC response is connected
primarily to the MAO A affinity, intrinsic activity could be an additional link in the relationship
between structure, in vivo response and in vitro response.
Compound 16 has been fitted in the active site of the D2 receptor using the docking method
published by Malo et al.92
(Figure 17) and according to this model the oxygen atoms in the
methylsulfone-group show possible hydrogen bond interactions with both Ser193 and His393 while
the protonated nitrogen interacts with Asp114. In addition, a hydrophobic interaction is feasible
between the phenyl ring of the ligand and Phe389 in the binding site. The "agonist-fit" of 16
together with the low affinity is the likely reasons for the unique profile of this compound. Since 16
prefer the high-affinity state of the D2 receptor it is more prone to bind when DA is present and it is
also able to displace the endogenous ligand. However, once DA is displaced, the low affinity of 16
enables it to leave the receptor quickly and thus make way for DA to bind again. The impact on
normal DA surges is therefore minimal while the hyperdopaminergic states can be efficiently
inhibited.
Figure 17. Pridopidine (16) in the active site of D2 with possible interactions to aromatic acids marked
(dotted lines).
Phe389
His393
Ser193 Asp114
60
61
7. Concluding remarks
A set of mono-substituted 4-phenylpiperidines and 4-phenylpiperazines have been synthesized and
evaluated in vivo and in vitro for their effect on the dopaminergic system. The levels of DOPAC in
striatum were measured for all compounds and the behavioural effects were reported for a chosen
subset. Binding affinities to D2 and MAO A as well as intrinsic activity and receptor kinetics was
determined for some of the compounds in order to investigate the mechanisms behind the in vivo
effects. Based on these data, the structural requirements for intrinsic activity at D2 in this class of
compounds have been elucidated and a method for obtaining D2 antagonists which preferentially
displaces an agonist over an antagonist and have fast dissociation rates from the receptor are
described. This has also led to the discovery of the dopaminergic stabilizer pridopidine which has
been shown to display low affinity and surmountable D2 antagonism with a preference for binding
to the active conformation of the receptor. These properties, together with a fast dissociation rate
once bound to the receptor, would allow an attenuated physiological neurotransmission to persist in
the normal state while hyperdopaminergic conditions are effectively inhibited.
In addition, QSAR models with physicochemical descriptors set against the different
pharmacological responses (i.e. DOPAC, Ki(D2) and Ki(MAO A)) have led to an improved
understanding of how the observed effects are related. A strong correlation between the affinities to
D2 and MAO A and the levels of DOPAC in striatum has been established and the structural
properties that are linked to each response have been annotated. The location of the aromatic
substituent have proven utterly important for the pharmacological effects and distinct properties,
such as D2 antagonism, D2 partial agonism and MAO A inhibition, can be produced by substituting
different positions with functional groups of altering physicochemical properties. An electron-
donating substituent in the para-position produces a MAO A inhibitor, having only minor
interactions with the D2 receptor. Any substituent in the ortho-position yields a D2 antagonist while
the meta-substituted compounds are more diverse, acting either as D2 antagonists or partial agonists.
Although the ortho- and meta-substituted compounds mainly affect the D2 receptor, they can also
have some MAO affinity depending on the physicochemical properties of the substituent.
The QSAR models and assimilated understanding of the mechanisms underlying the in vivo
effects can be used to discover novel dopaminergic ligands with a desired pharmacological profile
and future use as CNS active drugs for a wide variety of diseases and symptoms.
62
63
8. Acknowledgement
The work included in this thesis was carried out at Carlsson Research which later became
Neurosearch Sweden. A lot of people have been part of making this work possible and I want to
thank them all for their contributions. In specific I want to thank:
My adviser Clas Sonesson, who always has taken the time to explain the theories, read my endless
drafts and provide the feedback needed for completing both the articles and this thesis. But above
all I want to express my sincere thanks to him for being such an inspiring role model and for
planting the seed to my striving towards a PhD degree.
My examinator Kristina Luthman, for taking me on as a PhD student and with an exceptional eye
for details helping me get all my manuscripts in shape.
Peder Svensson, for his fantastic commitment in the research behind this thesis and for the
willingness to sacrifice spare time in order to get the work done in time.
Cecilia Mattsson, for always having the time for discussions, regardless of the subject and for
keeping me company when I needed it the most.
Lars Swanson, for your sympathetic ways of letting me take the time needed to pursue my degree.
My friends and colleagues over the years at the chemistry department, Maria Gullme, Anna Sandal,
Mikael Andersson, Håkan Schyllander, Jonas Karlsson, Rickard Sott, Fariba Jam, Elin Hammar and
Anette Nydén for the assistance in the synthetic work and for making the cold and noisy lab a
wonderful work-place.
My co-workers over the years at the biology/pharmacology departments, Elisabeth Ljung, Marianne
Thorngren, Ingrid Berg, Katarina Rydén Markinhuhta, Theresa Andreasson, Kirsten Sönniksen,
Jenny Börjesson, Malin Edling, Boel Svanberg, Anna Carin Jansson, Anne Fagerberg, Britt-Mari
Larsson and Thérese Carlsson for their helpfulness, kindness and unparalleled skills that made this
work possible. And a special dedication to Lena Wolter, who recently passed away but will always
be remembered as a warm-hearted and caring person and an excellent microdialysis technician.
64
Sören Lagerkvist, for building and maintaining the best and most complex HPLC system ever
known to man.
Stellan Ahl, for always being helpful with all the technical issues.
Andreas Stansvik and Johan Kullingsjö, for their help with calculations and making the immense
amount of data available.
Nicholas and Susanna Waters, Henrik Pontén, Peter Martin and Daniel Klamer for sharing their
wisdom in the field of pharmacology, allowing me to explore the world outside the fume-hood.
Ritva Klinton and Cecilia Stenberg, for their endless strive to keep track on every number on every
paper in every binder, just to make sure I got my paycheck every month.
Ylva Sunesson, for taking the time and help getting the final manuscript done in time.
Marcus Malo, for the swift calculations and colourful pictures.
My friends, for their constant encouraging words and especially Johan and Nina for taking care of
Sofia during my many late evenings in front of the computer.
My parents-in-law, Desmond and Marie for their caring and generous ways.
My sister, Erica and her family for their love and support.
My father, Lars-Åke for teaching me gratitude and for always believing in me.
My family
Andreas, for being such a loving and kind person that always treat others with respect
My wife Jeevani, for your love and devotion that got me through this ordeal. I love you very much.
Sofia, min älskade dotter. Förlåt att jag varit borta så mycket, nu kan vi äntligen åka och bada.
65
9. Appendices
Appendix A
Table A1. Singlepoint displacement data of selected compounds on
DAT and NET
Compound DAT (h)
(1μM)
NET (r)
(1μM)
NET (h)
(1μM)
16
9
47
10
48 6
-1
54 -9
11
68
-12
73 -5
-4
76 7
-3
82
-13
83 -12
-4
84 -2 -9 0
91 -2
22
92 36
11
93 -3
5
The results are expressed as a percent of control specific binding obtained in the presence of
the test compounds from the assays listed below. Data are obtained from Cerep (Poitiers,
France).
Assay
Reference Compound IC50 (M) Ki (M) nH
NE transporter (h)
protriptyline 5.5E-09 4.1E-09 1.4
DA transporter (h)
BTCP 1.1E-08 5.6E-09 1.2
66
67
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